Chemical Composition Distribution of Ethylene-1-Hexene Copolymer

Macromolecules 1991,24, 1469-1472

1469

Chemical Composition Distribution of Ethylene-1-Hexene Copolymer Prepared with TiCl3-Al(C2H5)2C1 Catalyst Masahiro Kakugo,' Tatsuya Miyatake, and Kooji Mizunuma Chiba Research Laboratory, Sumitomo Chemical Co. Ltd., 2-1 Kitasode, Sodegaura-cho, Kimitu-gun, Chiba 299-02, Japan Received April 26, 1990; Revised Manuscript Received August 28, 1990 ABSTRACT The temperature-programmed column fractionation (TPCF) technique has been successfully used to investigate the chemical composition distribution of ethylene-1-hexene (EH) copolymer containing 52.0 mol % ethylene which was prepared with TiC&-Al(C2H&Cl catalyst. EH copolymer was fractionated accordingto only the crystallinity of the ethylene sequence,exhibitinga trimodal distribution: the predominant peak is located at 28 mol % ethylene, the middle peak near 100 mol % ethylene, and the lowest peak at 80 mol % ethylene. The first polymer contains isotactic 1-hexenetriads. It has been shown from *3CNMR data and the reactivities of the active centers that a highly isospecific center and a nonstereospecificcenter produce the first and second polymers, respectively. The last polymer was degraded at 330 "C under pure argon and fractionated again by the TPCF technique. This polymer is a block copolymer consisting of a long copolymer containing 66 mol ?6 ethylene and polyethylene blocks. The formation of the block copolymer is elucidated in terms of the configurational change of the low isospecific center during polymerization. A schematic model of the active center relevant to the block copolymer is shown.

Introduction Heterogeneous Ziegler-Natta catalysts give ethylenea-olefin copolymers with a wide chemical composition distribution.' We recently studied the origin of such a wide composition distribution by using I3C NMR and temperature-programmed column fractionation (TPCF)." The wide distribution was found to be primarily due to the presence of multiple active centers residing in the heterogeneous catalysts: isospecific,stereoblock, and nonstereospecific centers produce copolymers with increasing ethylene content in this order.3 Furthermore, TPCF of ethylene-propylene (EP) copolymers has shown that the copolymers consist of three types polymers, i.e., random copolymer containing a low percentage of ethylene, block copolymer containing a high percentage of ethylene, and p~lyethylene.~From these findings we have concluded that isospecific,stereoblock, and nonstereospecific centers produce random copolymer, block copolymer, and polyethylene, respe~tively.~ In addition, we have shown that two isospecific centers reside in the heterogeneous catalysts.6 We are thus interested in revealing which of the isospecific centers is relevant to the stereoblock center. Fortunately, activity toward ethylene is different between the isospecific center^,^ which could provide us with valuable information. The objective of the present study is to know the chemical composition distribution of ethylene-1-hexene (EH) copolymer and specifically to obtain information on the block copolymer fraction. As described previ~usly,~ TPCF takes place according to the degree of crystallinity of polymer and, therefore, has substantial limitations if applied to copolymers having many crystalline blocks such as EP copolymer. Since isotactic poly(1-hexene) is soluble in hydrocarbon solvent even a t room temperature, EH copolymer would be expected to be fractionated only on the basis of ethylene content. As a result, EH copolymer has been successfully fractionated according to expectation, showing a wide chemical composition distribution. The block copolymer fraction obtained has been slightly degraded at elevated temperature and then fractionated again by TPCF. This fraction has been proven to consist of long ethylene and copolymer blocks. On the basis of 0024-929719112224-1469$02.50/0

these results we discuss here the origin of the block copolymer.

Experimental Section Sample Preparation. The EH copolymer was prepared in an agitated 1-L autoclave at 60 f 1 "C for 1 h in the presence of 0.65 mmol of &Tic13 (TAC-131 grade, supplied by Toho Titanium Co.) and 12.5 mmol of Al(C2H&Cl (supplied by Nippon Aluminum Alkyls). 1-Hexene (0.5 L) dried over molecular sieves 13X was fed into the autoclave, which was heated to the prescribed temperature. After a gaseous mixture of ethylene and hydrogen as a chain-transfer agent (9614 mol/mol) was fed to a pressure of 3.5 atm, the catalysts were added to initiate the polymerization. Additional ethylene was fed so as to keep the pressure at 3.5 atm, and the copolymerization was terminated at 10% conversion of 1-hexene into the copolymer by the addition of isobutanol. The catalyst residue was extracted with a mixture of 1 N HCl and methanol (111(v/v)). Thermal degradation of the polymer was carried out at 330 OC for 7 h in an atmosphere of pure argon. Ten grams of the sample was put into a 100-mL glass flask. The atmosphere was replaced with argon by evacuationand fillingwith argon severaltimes before degradation. Temperature-Programmed Column Fractionation (TPCF). Forty grams of the sample was dissolved at 130 "C in xylene, and then 1200g of sea sand (35-48 mesh) kept at 130 "C was put into the solution. The mixture was cooled gradually to -30 "C and then put into a column (74 mm in diameter and 435 mm in height) immersed in an oil bath kept at -30 "C. The first fraction was eluted at -30 "C by dropping xylene into the column. Five hundred milliliters of xylene was used to elute each fraction. However, when a precipitate or milky turbidity appeared by addition of the last several droplets of the eluate into methanol, some additional xylene was used until one or the other did not appear. The consecutive fractions were obtained by raising stepwise the elution temperature to 100"C. The elution temperature was controlled within f O . l "C. Each polymer fraction was precipitated by addition of the eluate into 2.5 L of methanol, recovered by filtration, and dried in vacuo. The elution temperature was raised stepwise from 0 to 100 "C. The degraded sample was fractionated in a similar manner, but the amounts of the sample and sea sand were reduced to 5 and 700 g, respectively, and the first fraction was eluted at 0 "C. Characterization of Polymer. Intrinsic viscosity ( [ q ] )was measured at 135 OC in tetralin. The number-average molecular weight was calculated by the equation [ q ] = 4.60 X lO-'M0.7~.6 GPC measurements were carried out at 140"C in o-dichlorobenzene on a Waters 150C GPC using two Shodex M-80mixed 0 1991 American Chemical Society

Macromolecules, Vol. 24,No. 7,1991

1470 Kakugo et al.

Table I Fractionation of Ethylene-1-Hexene Copolymer Containing 52 mol % Ethylene Prepared with TiCla-Al(C2H~)&lCatalyst elution amt, ethylene obsd triads frac no. temp, O C wt% content, mol % HHH HHE EHE HEH EEH EEE 0-1 0-2

-30 0 30 50 60 70 80

0-3 0-4

0-5 0-6 0-7 0-8 0-9 0-10

79.8 1.5 1.4 1.1 1.4 2.0 1.8 1.9 5.8 2.9

90 95 100

28 60 73 78 82 84 92 95 100 100

0.50 0.16 0.08 0.06 0.05 0.04 0.02

0.01

0.16 0.13

0.06 0.11 0.11 0.10 0.08 0.07 0.06 0.03

0.08

0.06 0.05 0.04 0.02 0.01

0.08 0.07 0.06 0.04 0.03 0.02 0.01 0

0.11 0.20 0.19 0.17

0.15 0.13 0.12 0.06

0.09 0.33 0.48 0.51 0.64 0.69 0.79 0.89 1.00 1.00

1 oc

ae I-

z

5W

5c

W

5J 0

0

50

100

I

ELUTION TEMPERATURE ('C)

Figure 1. Ethylene content of the fractions obtained from ethylene-1-hexene copolymer containing 52 mol % ethylene vs elution temperature.

Figure 2. Bird's-eye view of the chemical composition and the molecular weight distribution for ethylene-1-hexene copolymer containing 52 mol % ethylene. +c1-c2 j

c3 c4

columna. lSC NMR spectra were obtained at 135 O C on a JEOL FX-100 pulsed Fourier transform NMR spectrometer. Samples were prepared as 10% (w/v) solutions of polymer in o-dichlorobenzene. Tetramethylsilane was added to the solutions as an internal chemical shift reference. The pulse interval was 10 s, the acquisition time was 4.2 s, the pulse angle was 4 5 O , and the number of transients accumulated was 2000. The signal assignment was made according to Hsieh and Randall.' The triad sequence distributions were calculated from the resonances of the methine and the methylene carbons.

Results and Discussion Fractionationof EH Copolymer. The EH copolymer containing 52 mol 5% ethylene was fractionated by TPCF. Table I summarizes the fractionation data and the triad distributions of the fractions obtained. As plotted in Figure 1, the ethylene content of the fractions increases monotonically from 28 to 1005% ethylene with an increase in elution temperature. This shows that the fractionation was carried out on the basis of ethylene content according to expectation and the chemical composition distribution is very broad. The molecular weight distribution of each fraction obtained was measured by GPC. From these data, a bird's-eye view of the chemical composition and the molecular weight distribution is depicted in Figure 2, where three peaks can be seen. The highest peak (peak l),the abundance of which reaches 80 w t % of the whole polymer, is located a t ca. 28% ethylene, the middle one (peak 3) near 100% ethylene, and the lowest one (peak 2) a t ca. 80 % ethylene. This trimodal distribution apparently resembles that observed by Hosoda for ethylene-1-butene copolymers (linear low-density polyethylene) produced with heterogeneous catalysts.8 The catalyst system used here is highly isospecific, producing more than 90 5% isotactic polypropylene. As described previously,3 the highly isospecific active center is the lowest in relative activity toward ethylene among the active centers, i.e., both the high and low isospecific,

I

36

35

33

34

PPm

Figure 3. 13C NMR spectrum of fraction 0-1 obtained from ethylene-1-hexene copolymer containing 52 mol % ethylene. the stereoblock, and the nonstereospecific active centers. The most abundant polymer (peak 1)contains the lowest ethylene and isotactic HHH sequence as seen in the 13C NMR spectrum shown in Figure 3. That is, the strong signals seen at 33.65 and 35.34 ppm are assigned to the methine and methylene resonances in the central monomer unit of the isotactic HHH sequence, respe~tively.~Jo This finding leads us to the conclusion that the peak 1polymer was produced with the highly isospecific active center. On the other hand, we have shown that the nonstereospecific center is the most active toward e t h ~ l e n e .Therefore, ~ the nonstereospecific center probably produced the peak 3 polymer containing the highest ethylene. The peak 2 polymer has a wide composition distribution ranging from 60 to 95 mol ?4 ethylene. This polymer will be assumed to be produced with the stereoblock active center. To make this point clear, we have characterized a more detailed molecular structure of the peak 2 polymer. Fractionationof Thermally Degraded Polymer. If the peak 2 polymer was produced with the stereoblock center, it will be expected to consist of different long blocks.

Chemical Composition of Ethylene-1-Hexene Copolymer 1471

Macromolecules, Vol. 24, No. 7, 1991

Table I1

Refractionation of the Block CoDolymer Fractions. of the Ethylene-1-Hexene Copolymer after Thermal Degradation elution

frac no.

temp, "C

D- 1 D-2 D-3 D-4 D-5 D-6 D-7 original

0 30 50

a

ethylene content, mol %

amt, wt % 10.6 3.0 10.6 18.2 26.2 28.3 3.0

60

70.1 80.1 above 90

obsd triads

HHH

HHE

EHE

HEH

66

0.09

0.11

0.14

0.08

90 93 95 97 100 88

0.02

0.03

0.01

0.01

0.06 0.05 0.04 0.03 0.06

0.01 0.03

0.03

EEH

EEE

0.21

0.37

0.01

0.12 0.11 0.09 0.07

0.02

0.13

0.77 0.82 0.86 0.90 1.00 0.74

'

A mixture of the 0-6 and 0-7 fractions in Table I; average ethylene content, 87.8 mol % .

io4

io3

io5

io6

Figure 5. Bird's-eye view of the chemical composition and the molecular weight distribution for the block copolymer fractions of ethylene-1-hexene copolymer after slight thermal degradation.

10'

Mw

Figure 4. GPC curves of ethylene-1-hexene copolymer containing 52 mol % ethylenebefore and after thermal degradation: (A) after degradation; (B)original sample. Therefore, there is a possibility that one can separate the constituent blocks by refractionation of slightly degraded fractions. Thus, we have intended to conduct such experiment. polymer fradion polymer1

0-1

- 0-2 -0-3

fraction

D- 1 D-2 36

D-4

-0-8

D-5

D-6

0-7

Fractions 0-6 (84 mol 74 ethylene) and 0-7 (92 mol % ethylene), after being completely mixed in hot xylene, were recovered by precipitating with an excess of methanol and dried in vacuo. The mixture wad degraded under an inert atmosphere from 1.8 to 1.0 dL/g in intrinsic viscosity. The number-average molecular weight (Mn)calculated from the intrinsic viscosity decreased from 9.0 X lo4to 4.0 X lo4, which means that the average number of chain scissions per polymer chain was ca. 1.3. The GPC curves measured before and after degradation are shown in Figure 4. Mnon a polystyrene basis changes from 2 X 105 to 1 X lo5. This change is compatible with the result calculated from the change in viscosity. The fractionation data on the degraded sample are summarized in Table I1 with the I3C NMR analytical data.

35

34 PPm

33

Figure 6. 13C NMR spectra of fractions 0-2 (spectrum A), 0-3 (spectrum B), and D-1 (spectrum C) obtained from ethylene1-hexene copolymer. The degraded sample showed again a broad chemical composition distribution ranging from 66 to 100 mol 7% ethylene. The molecular weight distributions of these fractions were measured by GPC. A bird's-eye view of the chemical composition and the molecular weight distribution is depicted in Figure 5, showing a bimodal distribution. The higher peak is located near 100% ethylene and the lower one a t ca. 70 mol % ethylene. This figure clearly shows that this sample consists of long ethylene and long copolymer blocks, the lengths of which correspond to half of the original polymer chain length. Fraction D-1, viz., the copolymer block, which contains 66 mol 7% ethylene, is much higher in ethylene than fraction 0-1of the original sample, 28 mol 7% , and close to those of fractions 0 - 2 and 0-3 of the original sample, 60 and 73 mol %, respectively. The triad distribution is also very close to those of fractions 0 - 2 and 0-3. As shown in Figure 6, the 13CNMR spectra of fractions 0-2,O-3, and D-1 show the

Macromolecules, Vol. 24, No. 7, 1991

1472 Kakugo et al.

Active center

4 1

Stereospecificity

highly isospecific

&

configurational change

2

low isospecific [ -~t

Relative activity

-

3

4

syndiospecific

toward ethylene

nonstereospecific

1

medium

low

b

d 3-

9

high

high

[ bbdl copolymer 1

Figure 7. Relationshipamong the active centers,the stereospecificities,and the relative activity toward the ethylene-a-olefin copolymers obtained.

presence of the signal a t 33.65ppm (central tertiary carbon in the isotactic HHH sequence), which indicates that these fractions were formed with the isospecific center. In a previous paper,3 we have shown that the low isospecific center is about twice as active toward ethylene as the highly isospecific one. As described above, the most predominant fraction 0-1of the original sample can be considered to be formed with the highly isospecific center. The ethylene contents of fractions 0-2,O-3, and D-1 are about double that of fraction 0-1,which suggests that the low isospecific center is relevant to the formation of the block copolymer. On the basis of the Cossee and Arlman model,11J2 we have proposed that (1) the highly isospecific center consists of four firmly bound C1 ions, an alkyl group, and a C1 vacancy (model l),(2) the low isospecific center consists of a t least a loosely bound C1 ion, an alkyl group, and a C1 vacancy (model 2), and (3) the nonstereospecific center consists of two firmly bound C1 ions, a C1 ion, an alkyl group, and two C1 vacancy (model 4) as shown in Figure 7.'3 In addition, we have considered that the low isospecific active center, when there is no steric hindrance, will become syndiospecific (model 3).13 A configurational change of the C1 ion, the alkyl group, and the vacancy during polymerization, model 2 model 3 in Figure 7 , likely leads to the formation of isotactic-syndiotactic stereoblock polymer in homopolymeri~ation.'~ Moreover, we have showed that the stereoblock active center increases in relative activity toward ethylene with

-

a decrease in isotacticity, which indicates that the syndiospecific configuration is more active toward ethylene than the isospecific ~0nfiguration.l~ Thus, the change of the stereoblock active center during polymerization very likely produces block copolymer in ethylene-cy-olefin copolymerization. The conclusion to be drawn from these results is also shown in Figure 7 .

References and Notes (1) Lukach, C.A.; Spurlin, H. M. Copolymerization; Ham, G. E.,

Ed.; Wiley-Interscience: New York, 1964;Chapter IVA. (2) Kakugo, M.; Naito, Y.; Mizunuma, K.; Miyatake, T. Macromolecules 1982,15, 1150. (3) Kakugo, M.; Miyatake, T.; Mizunuma, K.; Kawai, Y. Macromolecules 1988,21,2309. (4) Kakugo, M.; Naito, Y.; Mizunuma, K.; Miyatake, T. Makromol. Chem. 1989,190,849. (5) Kakugo, M.; Miyatake, T.; Naito, Y.; Mizunuma, K. Macromolecules 1988,21 314. (6) Tung, L.H. J.Polym. Sci. 1959,36,287. ( 7 ) Hsieh, E.T.: Randall, J. C. Macromolecules 1982.. 15, . 1402. (8) Hosoda, S. Polym. J.'1988,20,383. (9) Soga, K.;Yanagihara, H. Makromol. Chem. 1988, 189,2839. (10) Nishiyama, Y.;Asakura, T. Polym. Prepr., J p n . 1987,36,2408. (11) Arlman, E. J.; Cossee, P. J . Catal. 1964,3,99. (12) Arlman, E. J. J. Catal. 1966,5,178. (13) Kakugo, M.; Miyatake, T.; Naito, Y.; Mizunuma, K. Makromol. Chem. 1989,190,505. I

Registry No. EH (copolymer),25213-02-9; &Ticla,7705-079;Al(CzH5)2Cl, 96-10-6.